Tuesday, April 1, 2008

Abstract Outline

This is my research topic's abstract outline, I think this summarizes rainwater harvesting enough to make the key points and at least interest the reader. If anyone has ideas or suggestions to improve my outline, please by all means let me know. References will be added later as this is still a draft.

ABSTRACT OUTLINE

Over 4000 years ago, rainwater harvesting technology was used by the Ancient Romans. Over time wells became more popular and in the process, rainwater harvesting lost appeal. Today, rainwater harvesting has been rejuvenated becoming one of the driving forces in green technology for buildings. This technology has grown in popularity throughout the world, especially in Australia its dry climate and limited access to water supply making water conservation a necessity. This report will evaluate what methods of rainwater harvesting can be applied to residential sites in Kamloops.

Kamloops experiences an average of only 270mm of precipitation per year (snow and rain combined). Kamloops is located in BC’s interior and east of the coastal mountain range; because of its geographical location near the mountains this produces a rain shadow effect where very little precipitation will fall in the city. This poses a problem especially in the summer months; there are often water restrictions because of low water reservoir concerns in Kamloops. In the fall or winter, heavy rainfall generally discharges through the stormwater drain system directly into rivers or streams, potentially carrying contaminants, increasing sediment levels, scouring banks and destroying habitat in the process. Through stormwater retention techniques and harvesting rainfall for future uses reduces the volumes produced by individual residences, easing the stress on stormwater services, as well as providing water for some domestic uses. About 40% of water usage in the summer is used for irrigating lawns and gardens, all, or most of which can be replaced by rainwater. This also reduces the volumes of treated potable water being used unnecessarily for irrigation. In heavy precipitation months, retaining water on site is very important to relieve volumes in storm sewers. The use of rain gardens or bioswales allows rainwater to infiltrate back into the ground as part of the rainwater cycle, in the process irrigating these gardens. A main point that must be addressed in order for Leadership in Energy and Environmental Design (LEED) certification points is the control of storm water and how it is treated on-site.

There are two methods of rainwater harvesting that will be examined; rain barrels (cisterns) and/or storage tanks, and rain gardens. Residential rain barrels are usually 60 or 90 gallon barrels that store the rain intercepted on the roof, conveyed to the gutters, and then transferred to the downspout where the pipe is directed into the barrel. The barrel supports a hose bib connection so gardens can be watered. Rain gardens are intentionally depressed areas that allow rainwater to collect, allowing infiltration and irrigation to the landscape. Storage tanks allow retention of water and recycling the water back into the house for non-potable usage. Submersible pumps in these tanks allow water supply to toilets, washing machines, dishwashers, and irrigation systems, which do not require potable water.

The technology of retaining rainwater and reusing it in the home is a great environmental initiative that should be implemented in homes that have difficulty controlling storm water, where there are a high percentage of impervious surfaces on the lot, or homes and yards that have restrictive water supplies. The Canadian government should encourage and reward developers and home owners that implement a rain capture and recycling system. This reports main focal point is to educate the construction industry on the value of onsite stormwater management, and methods available to control and retain stormwater for the benefit of the homeowners, local infrastructure (domestic water delivery and stormwater services), and the environment.

7 comments:

Morgan Turland said...

The abstract looks really great Derek, I like how you laid out your topic right at the start, and then carried on from there. It needs a little bit of proof-reading English wise, but I think the content is really good.

The last paragraph (top two sentences at least) definitely shows your opinions quite strongly (I'm not certain if this would be consider a bias, or just a recommendation?) but I think it's good to see some final recommendations put into the abstract.

Cari said...

Hey Derek,
I don't know if this will be any use to you but I thought it was a really cool idea. This site shows a design of a water harvesting system that produces water from the air and then stores it so it can be used as needed.

http://www.openarchitecturenetwork.org/node/926

Derek Anderson said...

Thanks for the look through Morgan. Ya I'm sort of on the edge of bias support for this, definitly need to be careful at the conclusion. Thanks for the site Cari, they use fog nets in Nepal to retrieve water and these upside down umbrellas are great. I'd like to keep it to just rainwater transfer, but I'm sure Gordon could use this site.

Jeremy Jones said...
This comment has been removed by the author.
Jeremy Jones said...

DEREK SICK PAGE YO!! REALLY LOVING THE GRAPHICS AND ALL THE SWEET VIDEOS OF OLD MEN. anyways to the matter at hand, I presume that you have a done a lot of research.

sorry for that. okay there is a PDF on residential downspout drainage systems.

http://www.corix.com/water_products/documents/5-Drainage_03_chamber_systems.pdf

Dale Parkes said...

This is a solid outline. I would recommend that you condense it some. Try not to repeat any ideas.
I agree that this is a worthy subject to pursue, but there are limitations. If the site does not get enough rain, then it is difficult to harvest. /i have also read about concerns regarding the spread of West Nile Virus because mosquitoes reproduce in standing water that can be found in swales. Green roofs are very expensive to install and may consume more water than can be supplied by rainwater, depending on what is planted. You may want to further restrict your topic as there is a lot to be covered here.

Jared said...

Hey Derek,

I was talking to our civil teacher and he mentioned a really cool idea that companies are starting to implement, and it is right up your ally. Its called the "milk crate" technology. During the initial site construction they dig big holes and fill them with stacked milk crates, and wrap those milk crates in plastic. What this does is it creates huge underground storage areas while keeping the necessary structure. Then they feed all the site run-off into these holes and store it there until they need it for irrigation or whatever else they need it for. Its really cool, i would imagine Dave would have alot more information than me.

Jared

Planning Outline

EDDT 231
Applied Research Project Outline


Project:
Determining what measures can be taken to keep storm water retained on-site, how it can be recycled back into the building envelope and show how they apply to a specific building site.

Methods:
1.) State why storm water retention should be implemented. Naturalize the land again; help improve eco-system, healthier subdivisions.

2.) Talk about the meaning of retention for a building site. Problems a building site may have in conveying storm run-off. Significance of retention.

3.) Apply a design to a residential/commercial building site. Show the design and specifications of storm water retention recycling systems on elevation, floor plan, and building site drawings.

4.) Explain the change of design standards for municipalities. Over-capacity storm sewers, re-charging ground water, reducing amount of runoff into streams.

5.) Give a background on the measures used to help retention. Show statistics based on several projects throughout North America. Green roofs, roof rainwater storage units, rain gardens.

6.) Talk to engineers at work about their experience on design storm water retention systems for subdivisions and try to implement a design to a specific site.

7.) Read government reports on green roofs and their retention capabilities. Find effectiveness of cisterns, rain gardens. Look at comparison of roof storage tanks specs.

8.) Can alternate storm water management that is applied be effective, appealing, cost efficient? Cost/Benefit of retention based design vs. conventional storm sewers.

Special Problems:
1.) Environmental impacts of conventional storm sewers. Damage to streams and the habitat of wildlife depending on those streams is a major concern. Pollutants can enter the storm system with little or no treatment and into the streams.

2.) Cost of storm water retention systems. Does it cost more than conventional systems? Less? Do the benefits of a retention friendly system outweigh the cost? Should cost even be an issue?

3.) Are retention measures effective? Show statistics of several projects throughout North America using retention systems and prove how they work. Draw a comparison between conventional sewers and retention systems.

4.) Where in North America will recycled storm retention systems be beneficial? Coastal regions, with large amounts of rainfall. Can these systems work in semi-arid regions, like Kamloops?

5.) How often do materials used in recycling practices need replacing? Do they wear down easily/need maintenance?

6.) Which methods of retention recycling are more effective? Does it matter on a given design? Can these methods be combined for a given project?

7.) How is greywater treated back into the building? What can this water be used for? What chemicals are used to clean the water?

Also:
1.) What scale of size should retention systems be to? Should rooftop storage tanks, rain gardens, and green roofs all be used in a single building?

2.) Performance of roof storm water retention tanks. What ones work better and take up less square footage to be effective enough?

3.) Rain gardens and above ground cisterns can promote growth to mosquito larva increasing the risk of West Nile virus. What measures are taken to prevent hatching? Sprinklers, additives to water?

4.) How can storm water retention recycled systems be integrated with other green technologies? Create hydro-electric energy with storm run-off?

5.) Calculating storm run-off flow. Manning’s equation or computer modeling techniques used in engineering offices to find out how much run-off will enter sewers and streams. Compare conventional sewer run-off to a recycling system.

6.) Do land values increase with implementation of greener storm water retention technology? Quality of life of those living in the building increase?